Network Interface Device

ABSTRACT

A network interface device having an FPGA for providing an FPGA application. A first interface between a host computing device and the FPGA application is provided, allowing the FPGA application to make use of data-path operations provided by a transport engine on the network interface device, as well as communicate with the host. The FPGA application sends and receives data with the host via a memory that is memory mapped to a shared memory location in the host computing device, whilst the transport engine sends and receives data packets with the host via a second memory. A second interface is provided to interface the FPGA application and transport engine with the network, wherein the second interface is configured to back-pressure the transport engine.

CROSS REFERENCE TO OTHER APPLICATIONS

This application is a continuation of U.S. application Ser. No. 15/847,778, entitled “NETWORK INTERFACE DEVICE” by Steven L. Pope, Derek Roberts, and David J. Riddoch, filed 19 Dec. 2017, (Atty. Docket No. LVL5 2054-1), which application is incorporated herein by reference in its entirety.

FIELD

This application relates to network interface devices having a field programmable gate array application.

BACKGROUND

Network interface devices are known and are typically used to provide an interface between a computing device and a network. The network interface device can be configured to process data which is received from the network and/or process data which is to be put on the network.

For some network interface devices, there is a drive to provide increased specializations of designs towards specific applications.

SUMMARY

According to a first aspect, there is provided a network interface device arranged to couple a host computing device to a network, said network interface device comprising: a first interface configured to receive data from the host computing device; a first field programmable gate array application; and a transport engine for processing data, wherein the first interface is configured to: direct at least some of the data received from the host to the first field programmable gate array application; and direct at least some of the data received from the host to the transport engine, wherein the first field programmable gate array application is configured to perform processing with respect to the at least some of the received data.

In one embodiment, the first field programmable gate array application is configured to pass the processed at least some of the data to the transport engine, wherein the transport engine is configured to perform processing of the at least some of the data received from the first field programmable gate array application and cause the processed data to be transmitted over the network.

In one embodiment, the network interface device comprises a second interface between the transport engine and the first field programmable gate array application, wherein the second interface is configured to receive at least one of: protocol processed data packets from the transport engine and data packets from the network, wherein the second interface is configured to pass the received data packets to the first field programmable gate array application for processing.

In one embodiment, in response to processing the received data packets, the first field programmable gate array application is configured to provide processed data packets to at least one of: the transport engine for protocol processing; and the second interface for transmission over the network.

In one embodiment, the network interface device comprises a second field programmable gate array application configured to at least one of: process data received from at least one of: the first interface and the first programmable gate array application; and provide data processed by the second field programmable gate array application to at least one of the: the first interface and the first programmable gate array application.

In one embodiment, the processing of the data received at the second field programmable gate array application comprises writing or reading from a data structure maintained by the second field programmable gate array application.

In one embodiment, the providing data processed by the second field programmable gate array application comprises providing data read from a data structure maintained by the second field programmable gate array application to at least one of: the first interface and the first programmable gate array application.

In one embodiment, in response to receiving a read request from the first interface or the first programmable gate array application, updating the data structure.

In one embodiment, the first interface is configured to direct data packets of a first data flow to the field programmable gate array application and to direct data packets of a second data flow to the transport engine.

In one embodiment, the transport engine is provided by application specific integrated circuit gates within a field programmable gate array also providing said first field programmable gate array application.

In one embodiment, said FPGA is configured to perform one or more of the following: reduce data in one or more flows; aggregate data in one or more flows; perform hybrid processing; detect a DDOS attack; machine learning; perform a software defined networking function; provide an Open Computing Language kernel offload; provide an offload function; and take remedial action against a distributed denial of service attack.

According to a second aspect, there is provided a network interface device arranged to couple a host computing device to a network, said network interface device comprising: a transport engine for performing protocol processing of data packets received from the network, a first field programmable gate array application; a first interface configured to receive processed data packets from the transport engine and to: provide at least some of the processed data packets to the field programmable gate array application for processing.

In one embodiment, the first interface is configured to: provide at least some of the processed data packets to the host computing device without being processed by the application.

In one embodiment, the first field programmable gate array application is configured to process the at least some of the data packets to provide filtering.

In one embodiment, the network interface device comprises: a second field programmable gate array application; a second interface between the transport engine and the second field programmable gate array application, wherein the second interface is configured to provide the data packets received from the network to the second field programmable gate array application, wherein the second field programmable gate array application is configured to process the data packets and provide them to the transport engine.

In one embodiment, the processing by the second field programmable gate array application comprises distributed denial of service (DDOS) mitigation, the first field programmable gate array application maintains a data store, the processing by the first field programmable gate array application comprises updating the data store.

According to a third aspect, there is provided a network interface device arranged to couple a host computing device to a network comprising: a first interface configured to receive data packets from the host computing device, the first interface comprising a first memory and a second memory, wherein the first memory is memory mapped to a shared memory location in the host computing device, wherein the second memory is configured to receive data packets transferred from the host, wherein the network interface device comprises: a field programmable gate array application; and a transport engine for performing protocol processing of data packets, wherein the first interface is configured to provide the data packets in the first memory to the FPGA application for processing by the FPGA application, wherein the first interface is configured to provide the data packets in the second memory to the transport engine for protocol processing.

According to a fourth aspect, there is provided a data processing system comprising: a network interface device according to the third aspect; and a host computing device.

In one embodiment, the FPGA application is configured to provide data to the host computing device, wherein the host computing device is configured to provide flow control over the data provided by the FPGA application to the host computing device.

In one embodiment, the flow control comprises credits based flow control.

In one embodiment, the flow control comprises Xon/Xoff flow control.

According to a fifth aspect, there is provided a data processing system comprising a host computing device and a network interface device arranged to couple the host computing device to a network, the network interface device comprising a field programmable gate array application and a transport engine, the host computing device comprising: one or more processors; a first memory configured to receive data packets for transmission over a network; a second memory configured to receive data packets for delivery to the field programmable gate array application, wherein the second memory is mapped to a memory region on the network interface device associated with the field programmable gate array application; a transmit queue comprising a pointer to a location in the first memory, wherein the one or more processors are configured to transfer data from the first memory at the location pointed to by the pointer to a memory of the network interface device associated with the transport engine.

In one embodiment, the second memory is mapped to the memory region associated with the field programmable gate array application using a wide memory aperture.

According to a sixth aspect, there is provided a network interface device arranged to couple a host computing device to a network comprising: a transport engine for performing protocol processing of data packets; a field programmable gate array application configured to process data packets to be sent over the network, wherein the transport engine is configured to perform protocol processing of data packets to be sent over the network, the network interface device comprising: a second interface configured to: receive data packets protocol processed by the transport engine; and cause the data packets to be transmitted over the network, wherein the second interface is configured to back-pressure the transport engine.

BRIEF DESCRIPTION OF DRAWINGS

Some embodiments will now be described by way of example only with reference to the accompanying Figures in which:

FIG. 1 shows a schematic view of a data processing system coupled to a network;

FIG. 2 shows a schematic view of a network interface device according to embodiments of the application;

FIG. 3 shows a schematic view of a network interface device according to embodiments of the application;

FIG. 4 shows a schematic view of a network interface device according to embodiments of the application;

FIG. 5 shows a schematic view of a network interface device according to embodiments of the application;

FIG. 6 shows a data processing system according to embodiments of the application; and

FIG. 7 shows a schematic view of a network interface device according to embodiments of the application.

DETAILED DESCRIPTION OF THE DRAWINGS

The following description is presented to enable any person skilled in the art to make and use the invention, and is provided in the context of a particular application. Various modifications to the disclosed embodiments will be readily apparent to those skilled in the art.

The general principles defined herein may be applied to other embodiments and applications without departing from the spirit and scope of the present invention. Thus, the present invention is not intended to be limited to the embodiments shown, but is to be accorded the widest scope consistent with the principles and features disclosed herein.

When data is to be transferred between two data processing systems over a data channel, such as a network, each of the data processing systems has a suitable network interface to allow it to communicate across the channel. Often the network is based on Ethernet technology. Data processing systems that are to communicate over a network are equipped with network interfaces that are capable of supporting the physical and logical requirements of the network protocol. The physical hardware component of network interfaces are referred to as network interface devices or network interface cards (NICs).

Most computer systems include an operating system (OS) through which user level applications communicate with the network. A portion of the operating system, known as the kernel, includes protocol stacks for translating commands and data between the applications and a device driver specific to the network interface devices, and the device drivers for directly controlling the network interface devices. By providing these functions in the operating system kernel, the complexities of and differences among network interface devices can be hidden from the user level application. In addition, the network hardware and other system resources (such as memory) can be safely shared by many applications and the system can be secured against faulty or malicious applications.

A typical data processing system 100 for carrying out transmission across a network is shown in FIG. 1. The data processing system 100 comprises a host computing device 101 coupled to a network interface device 102 that is arranged to interface the host to network 103. The host computing device 101 includes an operating system 104 supporting one or more user level applications 105. The host computing device 101 may also include a network protocol stack (not shown). For example, the protocol stack may be a component of the application, a library with which the application is linked, or be provided by the operating system. In some embodiments, more than one protocol stack may be provided.

The network protocol stack may be a Transmission Control Protocol (TCP) stack. The application 105 can send and receive TCP/IP messages by opening a socket and reading and writing data to and from the socket, and the operating system 104 causes the messages to be transported across the network. For example, the application can invoke a system call (syscall) for transmission of data through the socket and then via the operating system 104 to the network 103. This interface for transmitting messages may be known as the message passing interface.

Instead of implementing the stack in the host 101, some systems offload the protocol stack to the network interface device 102. For example, in the case that the stack is a TCP stack, the network interface device 102 may comprise a TCP Offload Engine (TOE) for performing the TCP protocol processing. By performing the protocol processing in the network interface device 102 instead of in the host computing device 101, the demand on the host system's 101 processor/s may be reduced. Data to be transmitting over the network, may be sent by an application 105 via a TOE-enabled virtual interface driver, by-passing the kernel TCP/IP stack entirely. Data sent along this fast path therefore need only be formatted to meet the requirements of the TOE driver.

The host computing device 101 may comprise one or more processors and one or more memories. In some embodiments, the host computing device 101 and the network interface device 102 may communicate via a bus, for example a peripheral component interconnect express (PCIe bus).

During operation of the data processing system, data to be transmitted onto the network may be transferred from the host computing device 101 to the network interface device 102 for transmission. In one example, data packets may be transferred from the host to the network interface device directly by the host processor. The host may provide data to one or more buffers 106 located on the network interface device 102. The network interface device 102 may then prepare the data packets and transmit them over the network 103.

Alternatively, the data may be written to a buffer 107 in the host system 101. The data may then be retrieved from the buffer 107 by the network interface device and transmitted over the network 103.

In both of these cases, data is temporarily stored in one or more buffers prior to transmission over the network.

Some embodiments relate to the transmission of data over a network from a data processing system. A data processing system could be any kind of computing device, such as a server, personal computer or handheld device. Some embodiments may be suitable for use in networks that operate TCP/IP over Ethernet. In other embodiments one or more different protocols may be used. Embodiments may be used with any suitable networks, wired or wireless.

Buffer 106 may be any suitable memory, a FIFO, or set of registers. The buffer may be such that any operations which require modifications to the frame (for example checksum insertion into headers) are completed before that portion of the frame is transferred to the MAC (media access control).

As mentioned, the protocol processing may be offloaded to the network interface device to be performed in the network interface. In the case that such offloading is performed at the network interface device, it may desirable to implement functionality on the network interface device that can make use of the protocol processing capabilities of the network interface device. By implementing such functionality in the network interface device instead of the host, potential improvements in latency may be achieved by reducing the data transfer between the host and the network interface device.

According to some embodiments of the application, a Field Programmable Gate Array (FPGA) application is provided on the network interface device. In some embodiments, the NIC functionality may embedded in an FPGA. The FPGA application may be understood to be an application that is implemented using an integrated circuit designed to be configured by a customer or designer after its manufacture. FPGAs may offer the ability to deploy a circuit which provides an application specific solution. An FPGA can allow for customization of a network interface device. Such applications may be niche or small volume applications. The FPGA is an array of programmable logic blocks. An FPGA may be characterised as being reprogrammable at the logic element granularity. An FPGA may be regarded as being an array of gates.

A first interface (for example a Fabric interface) may be provided in the network interface device between the FPGA application and the host computing device, the first interface being configured to receive data from the host and pass at least some of the data to the FPGA application. The data received from the host over the first interface for delivery to the FPGA application may be any type of data transaction. For example, the data may be a data packet having a payload and header according to a suitable network protocol. The data packet may be an egress data packet for transmission over the network. On the other hand, the data may be a “read” request for access to a data structure maintained by the FPGA application. In response to such a request (which may take the form of a local instructions issued to an address memory mapped to a memory accessible to the FPGA), the FPGA application may return the requested data to the host via the first interface. The data received could, in other words, be a lookup request received from the host. In some cases, the read operation from the host may cause side effects such as an update to data maintained by the FPGA application. For example, the FPGA could comprise a store/database (of, for example, a key value). The FPGA application may receive from the host an update to the store/database from the FPGA in the form of memory “write” instructions, which may take the form of a store instruction to a mapped address. The write could update a data structure or cause any other side effect as implemented by the FPGA.

If the first interface receives data for transmission over the network, the first interface may be configured to pass some of this data to the FPGA application for processing. The first interface may pass the remaining data to a transport engine for protocol processing and transmission over the network without it being processed by the FPGA application. The FPGA application may be configured to perform the processing of data packets it receives. In some cases (e.g. the data is for transmission over a network), the FPGA application is configured to then pass the processed data to the transport engine for protocol processing to form protocol processed data packets. Hence, the processing by the FPGA application is optional from the perspective of the first interface. The first interface has the capability to apportion work to the FPGA application. Once the protocol processing has been performed, the data packets are then transmitted over the network.

A second interface may be provided in the network interface device, for interfacing the device with the network. The second interface may be a Layer2 Streaming Interface. The second interface is configured to receive data packets from the FPGA application or from the transport engine and cause them to be transmitted over the network.

The network interface device is also configured to receive ingress data packets from the network and pass them to the host or the FPGA depending on a classification of the packets, e.g. MAC or virtual local area network (VLAN).

The transport engine is configured to receive some ingress data packets from the network and perform receive protocol processing of the data packet prior to passing at least some of the data packets to the first interface. The first interface is configured to receive these protocol processed data packets from the transport engine and pass some of them to the FPGA application. The first interface may be configured to cause the remaining data packets to be transmitted to the host without being processed by the FPGA application. The FPGA application may then be configured to perform processing of the data packets passed to it prior to the data packets being transmitted to the host via the first interface. The first interface may be configured to receive data packets from the FPGA application that have been processed by the FPGA application, and to pass these processed packets to the host computing device. Alternatively, instead of transmitting the data packets to the host, the FPGA application may be configured to process the data packets by terminating them. The FPGA application may be configured to process the data packets by consuming them. The FPGA application may process the data packets by filtering them and passing only some of them to the host.

In some embodiments, the second interface may be configured to receive data packets from the network and provide them to the FPGA application prior to protocol processing at the transport engine. The FPGA application may perform the processing of the data packets and may then pass the processed data packets to the transport engine. The transport engine is configured to receive the data packets from the FPGA application, protocol process them, and then pass them to the first interface to be transmitted to the host. The transport engine may backpressure the second interface. A third interface, which may be a MAC layer, may also be provided between the second interface and the network. The third interface may receive data packets from the network and provide them to the second interface. The third interface may be back-pressured by the transport engine or by the second interface.

A third interface, which may be MAC layer, may also be provided between the second interface and the network. The third interface may receive data packets from the network and provide them to the second interface.

In some embodiments, the transport engine may receive egress data packets from the host for protocol processing prior to them being passed to the FPGA application. The FPGA application may then process the protocol processed data packets prior to passing them to the second interface for transmission over the network. The second interface may be configured to pass the data packets to the third interface, which is configured to cause them to be transmitted over the network. The second interface may be back-pressured by the third interface. The transport engine may be back pressured by the second interface or the third interface.

The FPGA application may need to compete for host memory and PCI bandwidth used to communicate with the host. The FPGA application may also need to compete for network bandwidth. The FPGA application may need to compete for these resources with, for example, data flows being sent and received between the host and the network.

The backpressuring of the transport engine or the interfaces could, for example, be used to free up additional resources for the FPGA application. For example, the transport engine may be back-pressured by the second interface. This may free up resources for the FPGA application communicate over the network, by reducing the proportion of network resources in use for transmitting data packets from the transport engine.

Different techniques may be used by the network interface device for scheduling so as to allocate the resources appropriately. In one example, credit-base flow control may be implemented. For example, the FPGA application may have data to be written to the host. The FPGA application may make the transfer of data to the host in response to determining that sufficient credits are available for the making of the transfer of the data to the host. For example, the FPGA application may receive the credits from the host and, in response, to send the data to the host. The credits may be bus credits, such as PCIe tags. The credits may be sent by the first interface to both the FPGA application and the transport engine. The credits may be shared amongst the FPGA application and the transport engine. The credits may shared amongst the slices of the transport engine. By using this flow control method, the host may exert control over the resources used by the host.

In another example XOFF/XON flow control may be implemented. For example, the host may transmit to the network interface device XOFF/XON codes that indicate to the FPGA application whether or not data should be transmitted from the FPGA application to the host. The FPGA application may transmit data to the host in response to receiving an indication to transmit. The FPGA application may continue to transmit data to the host until an indication not to transmit is received. The FPGA application may then resume transmission until an indication to transmit is again received.

Some embodiments may have the advantage that the network interface device can be programmed to provide functions for the data packets in the receive path or on the transmit path as a customer or designer would see fit. These functions could be performed for only some or for all of the data packets on the receive path or transmit path.

As the FPGA application is provided with the first interface where the data paths also interface to the host, the FPGA application may make use of data path operations. For example the data path operation may be a checksum offload operation. The first interface may allow the network interface device to properly schedule work between host applications and the FPGA application. The FPGA application with this architecture is able to communicate with the other network interface device applications using a relative high bandwidth and/or relative low latency interconnect. Some embodiments may have the advantage that the FPGA application is integrated within the network interface functionality.

In some embodiments, a plurality of FPGA applications may be provided in the network interface device. The plurality of FPGA applications may be configured to perform different types of processing.

Some embodiments may support a significant amount of per-frame packet processing.

Reference is made to FIG. 2, which shows a network interface device 200 according some embodiments of the application.

The network interface device functionality may be embedded in an FPGA 205 in some embodiments. That FPGA 205 may have network interface functionality and FPGA functionality. The FPGA functionality may provide an FPGA application 240, which may programed into the FPGA 205 according to the needs of the network interface device user. The FPGA application 240 may, for example, provide filtering of the messages on the receive path from the network 230 to the host. The FPGA application 240 may provide a firewall.

The FPGA application 240 may be used for any suitable purpose. For example, the FPGA application 240 may reduce data in one or more flows. For example, the FPGA application 240 may remove duplicate messages in an arbitration application. The FPGA application 240 may alternatively or additionally be used to aggregate data. For example the FPGA may buffer and consolidate network captures for more efficient host delivery. Alternatively or additionally, the FPGA may be used for hybrid processing. For example the FPGA may provide a toolkit to enable hybrid applications to implement fast-path processing (low-latency) on the FPGA while using a slice to handle slower (and more complex TCP) protocol activity. This is also known as Delegated-Send on the transmit side. The FPGA may be used to detect frames which are part of DDOS attack. Those frames may be dropped or filtered. The FPGA may alternatively or additionally be used for machine learning with a neural network or the like.

The FPGA may be programmable to provide the FPGA application 240 using a high level programming language, such as C-based languages. The high level programming of the FPGA may be achieved using high level synthesis. The FPGA application 240 may implement a neural network and perform feature extraction or classification based on incoming frames.

In some embodiments, the network interface device functionality may be implemented as “hard” logic within the FPGA. For example, the hard logic may be Application Specific Integrated Circuit (ASIC) gates. The FPGA application 240 may be implemented as “soft” logic. The soft logic may be provided by programming the FPGA LUTs (look up tables). The hard logic may be capable of being clocked at a higher rate as compared to the soft logic.

The network interface device 200 includes a first interface 210 configured to receive data from the host 230. The first interface 210 may be a fabric interface. The first interface 210 interfaces the transport engine 215 with the host computing device 235. The first interface 210 also interfaces the FPGA application 240 with the host 235. The first interface may provide an application programming interface, allowing the host 235 to perform memory read and writes to memory associated with the FPGA application 240.

Some drivers may be associated with the memory interfaces. This allows host applications to directly access the FPGA application 240 from the host and make uses of the functions of the FPGA application 240 at the same time that the FPGA is used as a network interface device. The memory based interface may be mapped through a different PCI function than is used by the message passing interfaces. The message passing interfaces typically have one function per Ethernet port. The host software may attach a driver to each function and may attach the network stack to the interface to the network.

The network interface device 200 further comprises a transport engine 215, configured to process the data packets in accordance with a transport protocol, such as TCP/IP. The transport engine 215 may comprise a protocol stack. The transport engine 215 may comprise a plurality of slices or data pipeline, some of the slices being RX slices configured to perform receive processing of the ingress data packets received from the network 230, and some of the slices being TX slices configured to perform transmit processing of the egress data packets to be transmitted onto the network 230. In some embodiments, a slice may be able to handle both data to be transmitted and received data.

In the example shown, four slices are provided. However, it should be appreciated that in other embodiments, a different number of slices are used. In one embodiment, a slice may be arranged to process received data or to process data to be transmitted. In other embodiments, a slice may be arranged such that it is able to process received data and data to be transmitted. In some embodiments, the number of slices may be the same as the number of ports. In some embodiments, there may be a transmit slice and a receive slice for each port. In some embodiments, there may not be a direct correlation between the number of ports and the number of slices. In some embodiments, a slice can be switched dynamically from processing received data to processing transmitted data and vice versa.

Each slice may be regarded as a processing engine. Each slice may thus execute micro code to implement functions such as parsing, matching offload and delivery semantics for the data path. The slice may act on any bit of a frame.

The slices may perform a parsing action on the data which the slice is processing. There may be a matching action which matches the data against for example a filter and action function which performs an action or not in dependence on the result of the matching.

The network interface device 200 also comprises a second interface 220 configured to interface the transport engine 215 with the network 230 and configured to interface the FPGA application 240 with the network 230. The second interface maybe a layer 2 streaming interface. The second interface may provide an interface to the network 230 via a third interface 225. The third interface 225 may receive data packets from the second interface and cause them to be transmitted over the network 230. The third interface 225 may similarly receive data packets from the network 230 and pass them to the second interface 220. The third interface 225 may comprise a MAC interface. The third interface 225 may comprise a plurality of MAC interfaces. The third interface 225 may comprise one or more Physical Coding Sublayer (PCS) interfaces. The third interface 225 may comprise one or more Physical Medium Attachment (PMA) interfaces.

The fabric interface is configured to allow the co-resident FPGA application 240 to receive frames from the host. The FPGA application 240 may be able to transmit frames to the work with data path processing at the same bandwidth as the host PCI.

The layer 2 streaming interface is configure to allow the FPGA application 240 to receive frames form any active MAC layer interface and to transmit frames to a data path associated with that MAC.

The network interface device may provide functionality such as flow steering and low latency operation, hardware timestamping and clock synchronisation.

FIG. 2 shows a path that may be taken by ingress data packets upon their reception from the network 230. The third interface 225 is configured to receive the data packets from the network and pass them to the second interface 220. The second interface 220 is configured to pass the data packets to the transport engine 215, which performs processing of the data packets, prior to passing the processed data packets to the fabric interface 210. The fabric interface 210 is configured to pass some of the data packets to the host 235, and some of the data packets to the FPGA application 240. The fabric interface may determine to pass data packets of a first flow to the host 235 and data packets of a second flow to the FPGA 205. The data packets received at the FPGA application 240 are processed by the FPGA application 240, before being passed to the host 235. Hence, the FPGA 205 can provide accelerator functions for some data packets prior to them being received at the host 235.

As explained, the FPGA 205 may provide a plurality of FPGA applications. The FPGA 205 could provide a first application and a second application. In FIG. 2, it is shown that data may be directed from a first interface 210 to the first field programmable gate array application 240 for processing. Additionally, however, the first and second interface may be configured to direct data to a second field programmable gate array for processing.

Reference is made to FIG. 7, which shows an example of a network interface device 700 according to embodiments of the application. In this case, the FPGA 705 provides a first FPGA application 715 and a second FPGA application 710. The second interface 220 is configured to receive the data packets from the network and provide the data packets to the second FPGA application 710 for processing. The second FPGA application 710 may process the data by performing DDOS mitigation, such as searching the data packets for a DDOS attack and taking remedial action against a DDOS attack. The data packets may comprise updates to a data store, maintained by the first FPGA application 715. The second FPGA application 710 is configured to provide security by searching the data packets to detect any threats posed by the data packets and taking any action as required.

After processing by the second FPGA application 710, the second FPGA application 710 is configured to provide the data packets to the transport engine 215 for protocol processing. Once the data packets have been processed, they are passed to a first interface, which is configured to provide the data packets to the first FPGA application 715. The first FPGA application 715 is configured to process the data packets. The processing by the first FPGA application 715 may comprise updating the data store maintained by the first FPGA application 715 with the data contained in the data packets.

The host may also provide queries of the data in the data store maintained by the first FPGA application 715. In response to a query, the first FPGA application 715 may be configured to provide the requested data from the data store to the host 235.

Additionally, although not shown in FIG. 7, the first FPGA application 715 may communicate with the second interface 220 to send and receive data with the transport engine 215 and the network 230. The first FPGA application 715 may send data to the transport engine 215 on the receive path or the transmit path. The first FPGA application 715 may receive data from the transport engine 215 on the receive path or the transmit path. Additionally, although not shown in FIG. 7, the second FPGA application 710 may communicate with the first interface 210 to send and receive data with the transport engine 215 and the host 235. The second FPGA application 710 may send data to the transport engine 215 on the receive path or the transmit path. The second FPGA application 710 may receive data from the transport engine 215 on the receive path or the transmit path.

The first FPGA application 715 and the second FPGA application 710 may both have access to shared state, which they may use for communicating with each other.

Reference is made to FIG. 3, which shows the same network interface device 200 shown in FIG. 2, but, in this case, indicates a path that may be taken by data received from the host 235. The first interface 210 is configured to receive data from the host 235 and to direct some of the data to the transport engine 215 for processing without it first being processed by the FPGA application 240. The first interface 210 is also configured to transfer some data to the FPGA application 240 for processing by the FPGA application 240. Once the data have been processed by the FPGA application 240, the FPGA application 240 may be configured to transfer those data packets to the first interface, which is configured to pass them to the transport engine 215 for protocol processing. The transport engine 215 is configured to process the data it receives to produce protocol processed data packets prior to them being transmitted onto the network. The protocol processed data packets may be passed to the second interface 220 and subsequently the third interface 225 prior to their transmission onto the network 230.

As will be explained with reference to FIG. 6 below, a host application may communicate directly with the FPGA application 240 via memory mapping. The host application may write to a shared memory on the host 235, which is memory mapped to a memory accessible to the FPGA application 240. Hence, the FPGA application 240 may receive data written to the shared memory by the host 235. Likewise, the FPGA application 240 may write to the memory that is accessible to it, with that data being automatically copied from that memory to the memory of the host 235 so that it received by the host application 235.

In some cases, some data may be transferred to the transport engine 215 from the host 235 and some data may be transferred to the FPGA application 240 from the host 235 in parallel. For example, a first host application may transfer data to the transport engine 215 via the first interface, whilst a second host application is transferring data to the FPGA application 240 at the same time.

Reference is made to FIG. 4, which shows a network interface device 400 according to some embodiments of the application. The network interface device 400 is similar to the network interface device 200 shown in FIGS. 2 and 3, with like elements being indicated with like reference numerals. However, FIG. 4 shows the network interface device 400 having two separate MAC interfaces 405, 410. In this case, the two MAC interfaces 405, 410 may be understood to constitute the third interface. Each MAC interface may be associated with different slices of the transport engine. For example, the first MAC interface 405 may be associated with a first receive slice 415 a, such that data packets, which are received at the first MAC interface 405 are delivered by the second interface 220 to the first receive slice 415 a for receive processing. The first MAC interface 405 may also be associated with a first transmit slice 415 c, such that data packets for which transmit processing is carried out at the transmit slice 415 c are delivered by the second interface 220 to the MAC interface 405 for transmission over the network. The second MAC interface 410 may be associated with a second receive slice 415 b, such that data packets, which are received at the second MAC interface 410 are delivered by the second interface 220 to the second receive slice 415 c for receive processing. The second MAC interface 410 may also be associated with a second transmit slice 415 d, such that data packets for which transmit processing is carried out at the transmit slice 415 d are delivered by the second interface 220 to the second MAC interface 410 for transmission over the network.

FIG. 4 shows a path that may be taken by data packets upon reception from the network 230. The data packets may be received at the third interface (e.g. the second MAC interface 410) and be passed to the second interface 220. The second interface 200 may be configured to transfer some data packets to the transport engine 215 and other data packets to the FPGA application 240. The FPGA application 240 is configured to process the data packets and pass them (e.g. via the second interface) to the transport engine 215. The transport engine 415 is configured to process the data packets prior to passing them to the host via the first interface 210.

The transport engine 215 may be configured to back-pressure the second interface. The transport engine 215 comprises one or more buffers for storing data on which receive protocol processing is to be performed. If a large amount of traffic is received from the network 230, there is a risk of buffer overflow for the one or more buffers stored by the transport engine 215. Therefore, in this case, the transport engine 215 may provide an indication to the second interface 220 to reduce the rate of data transfer to the transport engine 215. The transport engine 215 may be configured to monitor buffer utilisation of the one or more buffers, and if the buffer utilisation gets too high to provide an indication of such to the second interface 220, which reduces the rate at which is provides data packets to the transport engine 215 for processing. Similarly, the second interface 220 may back-pressure the third interface, by providing the indication that the buffer utilisation is too high to the third interface. The third interface being then configured to reduce the rate at which it transfers data packets to the second interface 220. The back pressuring of the third interface may be specific to the MAC interface associated with the particular slice, which is configured to perform receive processing for that MAC interface. For example, if the second receive slice 415 b determines that the buffer utilisation of a buffer associated with this slice gets too high, an indication of such may be provided to the second MAC interface 410, which reduces the rate of transfer to the second receive slice 415 b.

Reference is made to FIG. 5, which shows the same network interface device 400 shown in FIG. 4, but, in this case, indicates a path that may be taken by egress data packets received from the host 235 for transmission onto the network 230. The data packets are received from the host 235 and transferred via the first interface 210 to the transport engine 215, which performs processing of the data packets and passes the data packets to the second interface 220. The second interface 220 is configured to pass some of the data packets to the third interface for transmission onto the network 230, without being processed by the FPGA application 240. The second interface 220 is configured to pass some of the data packets to the FPGA application 240. The FPGA application 240 processes the data packets and then passes them to the third interface 410 for transmission over the network.

In this case, the second interface 220 may back-pressure the third interface. The second interface 220 comprises one or more buffers for storing data on which receive protocol processing is to be performed. If a large amount of traffic is received at the second interface 220 for delivery to the network 230, there is a risk of buffer overflow for the one or more buffers stored by the second interface 220. Therefore, in this case, the second interface 220 may provide an indication to the transport engine to reduce the rate of data transfer to the second interface 220. The second interface 220 may be configured to monitor buffer utilisation of the one or more buffers, and if the buffer utilisation gets too high to provide an indication of such to the second interface 220, which reduces the rate at which is provides data packets to the third interface. Similarly, the third interface may back-pressure the second interface 220, by providing an indication that the buffer utilisation of the third interface is too high, the second interface 220 being then configured to reduce the rate at which it transfers data packets to the third interface.

The concepts explained with regard to FIGS. 2, 3, 4, 5, and 7 are not limited to those specific embodiments and may be combined.

Reference is made to FIG. 6, which illustrates how data may be transferred from the host 605 to the network interface device 610. As explained previously, the first interface 620 is configured to receive data from the host 605. The host 605 may make the determination as to which of these is to apply to particular data. The host 605 may transfer data using different methods to memory associated with the first interface 620. For example, the host 605 may memory map data to a first memory 615 of the first interface 620. The first interface 620 is configured to provide the data in the first memory 615 to the FPGA application 630. Alternatively, the host 605 may transfer data to a second memory 625 of the first interface 620. The first interface 620 then being configured to provide the data in the second memory 625 to the transport engine 635 for processing. The first memory 615 and the second memory 625 may each comprise one or more buffers.

The host comprise a memory 640, which is memory mapped to the memory 615 on the network interface device 610. The memory mapping may be such that a user level process/host application 670, which is configured to write to the memory 640, and the network interface device 610 both have access to shared memory to which data is written. When a user level process 670 running on the host transfers data to the memory 640, the data may be automatically transferred from the memory 640 to the memory 615.

The communication between the FPGA application 630 and the memory 640 of the host is bidirectional, i.e. the FPGA application can also transfer data to the host 605 as well as receive data from the host 605. To transfer data to the host 605, the FPGA application 630 is configured to write data to memory 615, the data being automatically transferred to memory 640, so that a user level process 670 running on the host may access the data from the memory 640.

The host 605 comprises a memory 645 at which data may be stored for transfer to the memory 625 of the network interface device 610. The data may be provided to the memory 625 from a second application 675 running on the host 605. Hence, the second application 675 may transfer data using this socket interface to the network interface device 610. The data in memory 625 is provided to the transport engine. The host 605 also comprises a transmit queue 650 comprising a series of pointers pointing to locations in the memory 645 from which data is to be transferred to the network interface device 610. The host may comprise a queue 655 identifying the next available location in the memory at which data is to be written by the application 675. The queues 650 and 655 may comprise FIFO buffers. The data may be stored in the buffer 645 at the next available location—as identified by the next pointer in the queue 655—by a user level process 675. A processor of the host device is configured to read the next pointer from the transmit queue 650 and read the data from the buffer 645 at the location identified by the pointer and transfer the data to the network interface device 610. The network interface device 610 is configured to store the data in memory 625 at a location identified by the next pointer in the receive queue 660. The data in memory 625 may then be provided to the transport engine 635 for protocol processing.

The communication between the transport engine 635 and the host 605 is also bidirectional. A similar memory transfer mechanism may be implemented for transfer of the data from the fabric interface to the host 605.

FIG. 6 also shows the second interface 660 and the third interface 665, for the sending and receiving of data from the network. Data may be transferred from the FPGA application 630 or the transport engine 635 to the second interface 660, which is configured to pass the data to the third interface 665. The third interface 665 is configured to cause the data to be transmitted over the network. On the receive path, the data may be received from the network at the third interface 665, and passed to the second interface 660. The second interface may transfer the data to the FPGA application 630 or to the transport engine 635.

The two data transfer methods shown in FIG. 6 may occur in parallel. For example, the interface used by the application 675 to transfer data to the transport engine 635 may be active at the same time as the interface used by the application 670 to transfer data to the FPGA application 630. Furthermore, these interfaces may be both in use by multiple applications in parallel. A plurality of host applications may be configured to write to memory 645 to transfer data to the transport engine 635 and a plurality of host applications may be configured to write to memory 640 to transfer data to the FPGA application 630. In some examples, both of the interfaces may have associated with it a driver and a software stack.

In some cases an application may be provided in the host that may be used to transfer state between the host 605 and the FPGA application. The application may be an Open Computing Language application. A shared memory (e.g. a memory aperture) may be mapped onto the application. The shared memory may be used to transfer state between parts of the application running on the host and parts on the FPGA. Hence, transfer of state between the host and the parts on the FPGA may be achieved.

The applicant hereby discloses in isolation each individual feature described herein and any combination of two or more such features, to the extent that such features or combinations are capable of being carried out based on the present specification as a whole in the light of the common general knowledge of a person skilled in the art, irrespective of whether such features or combinations of features solve any problems disclosed herein, and without limitation to the scope of the claims. The applicant indicates that aspects of the present invention may consist of any such individual feature or combination of features. In view of the foregoing description it will be evident to a person skilled in the art that various modifications may be made within the scope of the invention. 

1. A network interface device arranged to couple a host computing device to a network, said network interface device comprising: a first interface to the host computing device; transport processing circuitry for performing receive protocol processing of data received from the network, a field programmable gate array providing a field programmable gate array application; a second interface configured to receive data packets from the network and to: provide some of the data packets received from the network to the field programmable gate array application for processing; and provide others of the data packets received from the network to the transport processing circuitry without them being processed by the field programmable gate array application.
 2. A network interface device as claimed in claim 1, wherein the field programmable gate array application is configured to after processing the some of the data packets, pass the some of the data packets to the transport processing circuitry, wherein the transport processing circuitry is configured to perform receive protocol processing of the some of the data packets received from the field programmable gate array application and cause those data packets to be provided to the host computing device.
 3. A network interface device as claimed in claim 1, wherein the processing performed by the field programmable gate array application comprises writing or reading from a data structure maintained by the field programmable gate array application.
 4. A network interface device as claimed in claim 1, wherein the transport processing circuitry is provided by application specific integrated circuit gates within a field programmable gate array also providing said field programmable gate array application.
 5. A network interface device as claimed in claim 1, wherein the field programmable gate array provides a plurality of field programmable gate array applications including a first field programmable gate array application, wherein the field programmable gate array application configured to process the some of the data packets is a second field programmable gate array application of the plurality of field programmable gate array applications.
 6. A network interface device as claimed in claim 5, wherein the first interface is configured to: receive the processed data packets from the transport processing circuitry; and provide at least some of the received processed data packets to the first field programmable gate array application for processing.
 7. A network interface device as claimed in claim 6, wherein the data packets comprise updates to a data store maintained by the first field programmable gate array, wherein the processing performed by the second field programmable gate array comprises threat detection for the some of the data packets.
 8. A network interface device as claimed in claim 5, wherein the first field programmable gate array application and the second field programmable gate array application both have access to shared state, wherein the first field programmable gate array application and the second field programmable gate array application are configured to communicate with each other using the shared state.
 9. A network interface device as claimed in claim 1, wherein the transport processing circuitry is configured to back-pressure the second interface.
 10. A network interface device as claimed in claim 1, comprising a third interface configured to receive the data packets from the network and provide them to the second interface, wherein the second interface is configured to back-pressure the third interface.
 11. A network interface device as claimed in claim 1, wherein the second interface is a layer 2 streaming interface.
 12. A network interface device arranged to couple a host computing device to a network, said network interface device comprising: a first interface to the host computing device; transport processing circuitry for processing data for transmission over the network; a field programmable gate array providing a field programmable gate array application; and a second interface configured to receive processed data packets from the transport processing circuitry and to: direct some of the received processed data packets to the field programmable gate array application for processing; and cause others of the received processed data packets to be transmitted over the network without being processed by the field programmable gate array application.
 13. A network interface device as claimed in claim 12, wherein the field programmable gate array application is configured to, after processing the some of the received processed data packets, cause those data packets to be transmitted over the network.
 14. A network interface device as claimed in claim 12, wherein the transport processing circuitry is provided by application specific integrated circuit gates within a field programmable gate array also providing said field programmable gate array application.
 15. A network interface device as claimed in claim 12, wherein the field programmable gate array provides a plurality of field programmable gate array applications including a first field programmable gate array application, wherein the field programmable gate array application configured to process the some of the data packets is a second field programmable gate array application of the plurality of field programmable gate array applications.
 16. A network interface device as claimed in claim 15, wherein the first interface is configured to: receive data packets from the host computing device; provide at least some of the data packets received from the host to the first field programmable gate array application for processing; and provide at least some of the data packets received from the host to the transport processing circuitry to produce the processed data packets that are provided to the second interface.
 17. A network interface device as claimed in claim 15, wherein the first field programmable gate array application and the second field programmable gate array application both have access to shared state, wherein the first field programmable gate array application and the second field programmable gate array application are configured to communicate with each other using the shared state.
 18. A network interface device as claimed in claim 12, comprising a third interface configured to receive the data packets from the second interface and cause them to be transmitted over the network, wherein the third interface is configured to back-pressure at least one of: the second interface; and the transport processing circuitry.
 19. A network interface device as claimed in claim 12, wherein the second interface is a layer 2 streaming interface.
 20. A network interface device as claimed in claim 12, wherein the second interface is configured to determine to direct the some of the received processed data packets to the field programmable gate array application in dependence upon at least one classification of the some of the received processed data packets. 